idx_bus

PURPOSE

SYNOPSIS

DESCRIPTION

IDX_BUS   Defines constants for named column indices to bus matrix.
   Example:

   [PQ, PV, REF, NONE, BUS_I, BUS_TYPE, PD, QD, GS, BS, BUS_AREA, VM, ...
   VA, BASE_KV, ZONE, VMAX, VMIN, LAM_P, LAM_Q, MU_VMAX, MU_VMIN] = idx_bus;

   Some examples of usage, after defining the constants using the line above,
   are:

    Pd = bus(4, PD);       % get the real power demand at bus 4
    bus(:, VMIN) = 0.95;   % set the min voltage magnitude to 0.95 at all buses
 
   The index, name and meaning of each column of the bus matrix is given
   below:

   columns 1-13 must be included in input matrix (in case file)
    1  BUS_I       bus number (positive integer)
    2  BUS_TYPE    bus type (1 = PQ, 2 = PV, 3 = ref, 4 = isolated)
    3  PD          Pd, real power demand (MW)
    4  QD          Qd, reactive power demand (MVAr)
    5  GS          Gs, shunt conductance (MW demanded at V = 1.0 p.u.)
    6  BS          Bs, shunt susceptance (MVAr injected at V = 1.0 p.u.)
    7  BUS_AREA    area number, (positive integer)
    8  VM          Vm, voltage magnitude (p.u.)
    9  VA          Va, voltage angle (degrees)
    10 BASE_KV     baseKV, base voltage (kV)
    11 ZONE        zone, loss zone (positive integer)
    12 VMAX        maxVm, maximum voltage magnitude (p.u.)
    13 VMIN        minVm, minimum voltage magnitude (p.u.)
   
   columns 14-17 are added to matrix after OPF solution
   they are typically not present in the input matrix
                   (assume OPF objective function has units, u)
    14 LAM_P       Lagrange multiplier on real power mismatch (u/MW)
    15 LAM_Q       Lagrange multiplier on reactive power mismatch (u/MVAr)
    16 MU_VMAX     Kuhn-Tucker multiplier on upper voltage limit (u/p.u.)
    17 MU_VMIN     Kuhn-Tucker multiplier on lower voltage limit (u/p.u.)
 
   additional constants, used to assign/compare values in the BUS_TYPE column
    1  PQ    PQ bus
    2  PV    PV bus
    3  REF   reference bus
    4  NONE  isolated bus

   See also DEFINE_CONSTANTS.

CROSS-REFERENCE INFORMATION

• check_feasibility CHECK_FEASIBILITY Returns the maximum constraint violation in p.u.
• makeBloss [BL2, BL1, BL0] = MAKEBLOSS(MPC)
• make_opf_feasible MAKE_OPF_FEASIBLE Attempts to relax constraints to make an OPF feasible.
• insolvablepf INSOLVABLEPF A sufficient condition for power flow insolvability
• insolvablepf_limitQ INSOLVABLEPF_LIMITQ A sufficient condition for power flow insolvability
• makeIncidence MAKEINCIDENCE Builds the bus incidence matrix.
• sdpopf_solver SDPOPF_SOLVER A semidefinite programming relaxtion of the OPF problem
• t_insolvablepf T_INSOLVABLEPF Test for power flow insolvability condition
• t_insolvablepf_limitQ T_INSOLVABLEPF_LIMITQ Test for power flow insolvability condition
• t_insolvablepfsos T_INSOLVABLEPF Test for power flow insolvability condition
• t_insolvablepfsos_limitQ T_INSOLVABLEPF Test for power flow insolvability condition
• t_opf_sdpopf T_OPF_SDPOPF Tests for SDP-based AC optimal power flow.
• t_testglobalopt T_TESTGLOBALOPT Test for Global Optimality Condition
• testGlobalOpt TESTGLOABALOPT A sufficient condition for OPF global optimality
• doSE DOSE Do state estimation.
• getV0 GETV0 Get initial voltage profile for power flow calculation.
• outputpfsoln OUTPUTPFSOLN Output power flow solution.
• auction AUCTION Clear auction based on OPF results (qty's and lambdas).
• smartmkt SMARTMKT Runs the PowerWeb smart market.
• runse RUNSE Runs a state estimator.
• sgvm_acptdf SGVM_ACPTDF Calculate line sensitivitis at a given operating point.
• sgvm_add_shunts SGVM_ADD_SHUNTS add shunt elements to MPC to satisfy voltage constraints
• sgvm_minqflow SGVM_MINQFLOW minimize magintude of reactive flows by adding shunts
• syngrid SYNGRID Create a synthetic power grid model in MATPOWER format.
• t_syngrid T_SYNGRID Tests for syngrid().
• apply_changes APPLY_CHANGES Applies a set of changes to a MATPOWER case
• bustypes BUSTYPES Builds index lists for each type of bus (REF, PV, PQ).
• calc_branch_angle CALC_BRANCH_ANGLE Calculate branch angle differences across active branches
• case_info CASE_INFO Prints information about islands in a network.
• cdf2mpc CDF2MPC Converts an IEEE CDF data file into a MATPOWER case struct.
• compare_case COMPARE_CASE Compares the bus, gen, branch matrices of 2 MATPOWER cases.
• cpf_current_mpc CPF_CURRENT_MPC Construct MPC for current continuation step.
• cpf_flim_event_cb CPF_FLIM_EVENT_CB Callback to handle FLIM events
• cpf_plim_event CPF_PLIM_EVENT Event function to detect gen active power limit violations
• cpf_plim_event_cb CPF_PLIM_EVENT_CB Callback to handle PLIM events
• cpf_qlim_event CPF_QLIM_EVENT Event function to detect gen reactive power limit violations
• cpf_qlim_event_cb CPF_QLIM_EVENT_CB Callback to handle QLIM events
• cpf_vlim_event CPF_VLIM_EVENT Event function to detect bus voltage limit violations
• cpf_vlim_event_cb CPF_VLIM_EVENT_CB Callback to handle VLIM events
• dcopf_solver DCOPF_SOLVER Solves a DC optimal power flow.
• define_constants DEFINE_CONSTANTS Defines useful constants for indexing data, etc.
• ext2int EXT2INT Converts external to internal indexing.
• extract_islands function mpck = extract_islands(mpc, groups, k, custom)
• find_islands FIND_ISLANDS Finds islands in a network
• get_losses GET_LOSSES Returns series losses (and reactive injections) per branch.
• int2ext INT2EXT Converts internal to external bus numbering.
• load2disp LOAD2DISP Converts fixed loads to dispatchable.
• makeB MAKEB Builds the FDPF matrices, B prime and B double prime.
• makeBdc MAKEBDC Builds the B matrices and phase shift injections for DC power flow.
• makeJac MAKEJAC Forms the power flow Jacobian.
• makePTDF MAKEPTDF Builds the DC PTDF matrix for a given choice of slack.
• makeSbus MAKESBUS Builds the vector of complex bus power injections.
• makeSdzip MAKESDZIP Builds vectors of nominal complex bus power demands for ZIP loads.
• makeYbus MAKEYBUS Builds the bus admittance matrix and branch admittance matrices.
• nlpopf_solver NLPOPF_SOLVER Solves AC optimal power flow using MP-Opt-Model.
• opf OPF Solves an optimal power flow.
• opf_execute OPF_EXECUTE Executes the OPF specified by an OPF model object.
• opf_setup OPF Constructs an OPF model object from a MATPOWER case struct.
• opf_veq_fcn OPF_VEQ_FCN Evaluates voltage magnitude equality constraint and gradients.
• opf_vlim_fcn OPF_VLIM_FCN Evaluates voltage magnitudes and their gradients.
• opf_vref_fcn OPF_VREF_FCN Evaluates voltage angle reference and their gradients.
• pfsoln PFSOLN Updates bus, gen, branch data structures to match power flow soln.
• printpf PRINTPF Prints power flow results.
• psse_convert PSSE_CONVERT Converts data read from PSS/E RAW file to MATPOWER case.
• psse_convert_hvdc PSSE_CONVERT_HVDC Convert HVDC data from PSS/E RAW to MATPOWER
• psse_convert_xfmr PSSE_CONVERT_XFMR Convert transformer data from PSS/E RAW to MATPOWER
• runcpf RUNCPF Runs a full AC continuation power flow
• runpf RUNPF Runs a power flow.
• save2psse SAVE2PSSE Saves a MATPOWER case to PSS/E RAW format.
• savecase SAVECASE Saves a MATPOWER case file, given a filename and the data.
• scale_load SCALE_LOAD Scales fixed and/or dispatchable loads.
• t_apply_changes T_APPLY_CHANGES Tests for code in apply_changes.m.
• t_auction_minopf T_AUCTION_MINOPF Tests for code in auction.m, using MINOPF solver.
• t_auction_mips T_AUCTION_MIPS Tests for code in auction.m, using MIPS solver.
• t_auction_tspopf_pdipm T_AUCTION_TSPOPF_PDIPM Tests for code in auction.m, using PDIPMOPF solver.
• t_cpf T_CPF Tests for continuation power flow.
• t_dcline T_DCLINE Tests for DC line extension in TOGGLE_DCLINE.
• t_ext2int2ext T_EXT2INT2EXT Tests EXT2INT, INT2EXT, and related functions.
• t_get_losses T_GET_LOSSES Tests for code in GET_LOSSES.
• t_hessian T_HESSIAN Numerical tests of 2nd derivative code.
• t_islands T_ISLANDS Tests for FIND_ISLANDS, EXTRACT_ISLANDS, CONNECTED_COMPONENTS and CASE_INFO.
• t_jacobian T_JACOBIAN Numerical tests of partial derivative code.
• t_load2disp T_LOAD2DISP Tests for LOAD2DISP.
• t_loadcase T_LOADCASE Test that LOADCASE works with a struct as well as case file.
• t_makeLODF T_MAKELODF Tests for MAKELODF.
• t_makePTDF T_MAKEPTDF Tests for MAKEPTDF.
• t_opf_dc_bpmpd T_OPF_DC_BPMPD Tests for DC optimal power flow using BPMPD_MEX solver.
• t_opf_dc_clp T_OPF_DC_CLP Tests for DC optimal power flow using CLP solver.
• t_opf_dc_cplex T_OPF_DC_CPLEX Tests for DC optimal power flow using CPLEX solver.
• t_opf_dc_default T_OPF_DC_DEFAULT Tests for DC optimal power flow using DEFAULT solver.
• t_opf_dc_glpk T_OPF_DC_GLPK Tests for DC optimal power flow using GLPK solver.
• t_opf_dc_gurobi T_OPF_DC_GUROBI Tests for DC optimal power flow using Gurobi solver.
• t_opf_dc_ipopt T_OPF_DC_MIPS Tests for DC optimal power flow using MIPS solver.
• t_opf_dc_mips T_OPF_DC_MIPS Tests for DC optimal power flow using MIPS solver.
• t_opf_dc_mips_sc T_OPF_DC_MIPS_SC Tests for DC optimal power flow using MIPS-sc solver.
• t_opf_dc_mosek T_OPF_DC_MOSEK Tests for DC optimal power flow using MOSEK solver.
• t_opf_dc_osqp T_OPF_DC_OSQP Tests for DC optimal power flow using OSQP solver.
• t_opf_dc_ot T_OPF_DC_OT Tests for DC optimal power flow using Opt Tbx solvers.
• t_opf_default T_OPF_DEFAULT Tests for AC optimal power flow using default solver.
• t_opf_fmincon T_OPF_FMINCON Tests for FMINCON-based optimal power flow.
• t_opf_ipopt T_OPF_IPOPT Tests for IPOPT-based AC optimal power flow.
• t_opf_knitro T_OPF_FMINCON Tests for FMINCON-based optimal power flow.
• t_opf_minopf T_OPF_MINOPF Tests for MINOS-based optimal power flow.
• t_opf_mips T_OPF_MIPS Tests for MIPS-based AC optimal power flow.
• t_opf_model T_OPF_MODEL Tests for OPF_MODEL.
• t_opf_model_legacy T_OPF_MODEL_LEGACY Tests for OPF_MODEL, using the deprecated ADD_CONSTRAINTS.
• t_opf_softlims T_OPF_SOFTLIMS Tests for userfcn callbacks (softlims) w/OPF.
• t_opf_tspopf_pdipm T_OPF_TSPOPF_PDIPM Tests for PDIPM-based optimal power flow.
• t_opf_tspopf_scpdipm T_OPF_TSPOPF_SCPDIPM Tests for SCPDIPM-based optimal power flow.
• t_opf_tspopf_tralm T_OPF_TSPOPF_TRALM Tests for TRALM-based optimal power flow.
• t_pf_ac T_PF_AC Tests for AC power flow solvers.
• t_pf_dc T_PF_DC Tests for DC power flow solver.
• t_pf_radial T_PF_RADIAL Tests for distribution power flow solvers.
• t_runmarket T_RUNMARKET Tests for code in RUNMKT, SMARTMKT AND AUCTION.
• t_scale_load T_SCALE_LOAD Tests for code in SCALE_LOAD.
• t_total_load T_TOTAL_LOAD Tests for code in TOTAL_LOAD.
• t_vdep_load T_VDEP_LOAD Test voltage dependent ZIP load model for PF, CPF, OPF.
• toggle_dcline TOGGLE_DCLINE Enable, disable or check status of DC line modeling.
• toggle_softlims TOGGLE_SOFTLIMS Relax DC optimal power flow branch limits.
• total_load TOTAL_LOAD Returns vector of total load in each load zone.
• uopf UOPF Solves combined unit decommitment / optimal power flow.
• most MOST MATPOWER Optimal Scheduling Tool
• most_summary MOST_SUMMARY Collects and optionally prints a summary of MOST results.
• t_most_30b_1_1_0 T_MOST_30B_1_1_0 Tests for MOST.
• t_most_30b_1_1_0_uc T_MOST_30B_1_1_0_UC Tests for MOST.
• t_most_30b_3_1_0 T_MOST_30B_3_1_0 Tests for MOST.
• t_most_3b_1_1_0 T_MOST_3B_1_1_0 Tests for MOST.
• t_most_3b_3_1_0 T_MOST_3B_3_1_0 Tests for MOST.
• t_most_sp T_MOST_SP Tests of single-period continuous optimizations
• t_most_spuc T_MOST_SPUC Tests of single-period unit commitment optimizations
• t_most_suc T_MOST_SUC Tests of stochastic unit commitment optimizations.
• t_most_uc T_MOST_UC Tests of deteministic unit commitment optimizations
• t_most_w_ds T_MOST_W_DS Test for MOST with dynamical system constraints.

SOURCE CODE

0001 function [PQ, PV, REF, NONE, BUS_I, BUS_TYPE, PD, QD, GS, BS, BUS_AREA, VM, ...
0002     VA, BASE_KV, ZONE, VMAX, VMIN, LAM_P, LAM_Q, MU_VMAX, MU_VMIN] = idx_bus
0003 %IDX_BUS   Defines constants for named column indices to bus matrix.
0004 %   Example:
0005 %
0006 %   [PQ, PV, REF, NONE, BUS_I, BUS_TYPE, PD, QD, GS, BS, BUS_AREA, VM, ...
0007 %   VA, BASE_KV, ZONE, VMAX, VMIN, LAM_P, LAM_Q, MU_VMAX, MU_VMIN] = idx_bus;
0008 %
0009 %   Some examples of usage, after defining the constants using the line above,
0010 %   are:
0011 %
0012 %    Pd = bus(4, PD);       % get the real power demand at bus 4
0013 %    bus(:, VMIN) = 0.95;   % set the min voltage magnitude to 0.95 at all buses
0014 %
0015 %   The index, name and meaning of each column of the bus matrix is given
0016 %   below:
0017 %
0018 %   columns 1-13 must be included in input matrix (in case file)
0019 %    1  BUS_I       bus number (positive integer)
0020 %    2  BUS_TYPE    bus type (1 = PQ, 2 = PV, 3 = ref, 4 = isolated)
0021 %    3  PD          Pd, real power demand (MW)
0022 %    4  QD          Qd, reactive power demand (MVAr)
0023 %    5  GS          Gs, shunt conductance (MW demanded at V = 1.0 p.u.)
0024 %    6  BS          Bs, shunt susceptance (MVAr injected at V = 1.0 p.u.)
0025 %    7  BUS_AREA    area number, (positive integer)
0026 %    8  VM          Vm, voltage magnitude (p.u.)
0027 %    9  VA          Va, voltage angle (degrees)
0028 %    10 BASE_KV     baseKV, base voltage (kV)
0029 %    11 ZONE        zone, loss zone (positive integer)
0030 %    12 VMAX        maxVm, maximum voltage magnitude (p.u.)
0031 %    13 VMIN        minVm, minimum voltage magnitude (p.u.)
0032 %
0033 %   columns 14-17 are added to matrix after OPF solution
0034 %   they are typically not present in the input matrix
0035 %                   (assume OPF objective function has units, u)
0036 %    14 LAM_P       Lagrange multiplier on real power mismatch (u/MW)
0037 %    15 LAM_Q       Lagrange multiplier on reactive power mismatch (u/MVAr)
0038 %    16 MU_VMAX     Kuhn-Tucker multiplier on upper voltage limit (u/p.u.)
0039 %    17 MU_VMIN     Kuhn-Tucker multiplier on lower voltage limit (u/p.u.)
0040 %
0041 %   additional constants, used to assign/compare values in the BUS_TYPE column
0042 %    1  PQ    PQ bus
0043 %    2  PV    PV bus
0044 %    3  REF   reference bus
0045 %    4  NONE  isolated bus
0046 %
0047 %   See also DEFINE_CONSTANTS.
0048 
0049 %   MATPOWER
0050 %   Copyright (c) 1996-2016, Power Systems Engineering Research Center (PSERC)
0051 %   by Ray Zimmerman, PSERC Cornell
0052 %
0053 %   This file is part of MATPOWER.
0054 %   Covered by the 3-clause BSD License (see LICENSE file for details).
0055 %   See https://matpower.org for more info.
0056 
0057 %% define bus types
0058 PQ      = 1;
0059 PV      = 2;
0060 REF     = 3;
0061 NONE    = 4;
0062 
0063 %% define the indices
0064 BUS_I       = 1;    %% bus number (1 to 29997)
0065 BUS_TYPE    = 2;    %% bus type (1 - PQ bus, 2 - PV bus, 3 - reference bus, 4 - isolated bus)
0066 PD          = 3;    %% Pd, real power demand (MW)
0067 QD          = 4;    %% Qd, reactive power demand (MVAr)
0068 GS          = 5;    %% Gs, shunt conductance (MW at V = 1.0 p.u.)
0069 BS          = 6;    %% Bs, shunt susceptance (MVAr at V = 1.0 p.u.)
0070 BUS_AREA    = 7;    %% area number, 1-100
0071 VM          = 8;    %% Vm, voltage magnitude (p.u.)
0072 VA          = 9;    %% Va, voltage angle (degrees)
0073 BASE_KV     = 10;   %% baseKV, base voltage (kV)
0074 ZONE        = 11;   %% zone, loss zone (1-999)
0075 VMAX        = 12;   %% maxVm, maximum voltage magnitude (p.u.)      (not in PTI format)
0076 VMIN        = 13;   %% minVm, minimum voltage magnitude (p.u.)      (not in PTI format)
0077 
0078 %% included in opf solution, not necessarily in input
0079 %% assume objective function has units, u
0080 LAM_P       = 14;   %% Lagrange multiplier on real power mismatch (u/MW)
0081 LAM_Q       = 15;   %% Lagrange multiplier on reactive power mismatch (u/MVAr)
0082 MU_VMAX     = 16;   %% Kuhn-Tucker multiplier on upper voltage limit (u/p.u.)
0083 MU_VMIN     = 17;   %% Kuhn-Tucker multiplier on lower voltage limit (u/p.u.)